His scientific interests lie mostly in Molecular biology, Cell biology, Antibody, Proximity ligation assay and Complementarity determining region. The Molecular biology study combines topics in areas such as Transcription factor, ABL, Minimal residual disease, Myeloid leukemia and Transcription. His Transcription factor research incorporates elements of RNA-dependent RNA polymerase, Turn, DNA, Endogeny and Subcellular localization.
He interconnects Receptor, Cell culture and Transcription factories in the investigation of issues within Cell biology. The various areas that Ola Söderberg examines in his Proximity ligation assay study include Method development, Computational biology and Ligation. His Complementarity determining region study incorporates themes from Epitope, Gene rearrangement and Chronic lymphocytic leukemia.
Ola Söderberg mainly investigates Molecular biology, Proximity ligation assay, Cell biology, Computational biology and In situ. His specific area of interest is Molecular biology, where Ola Söderberg studies Ligation. His Proximity ligation assay research includes themes of Oligonucleotide, DNA, Microscopy, Protein–protein interaction and Flow cytometry.
His Cell biology research is multidisciplinary, incorporating perspectives in Cell culture, Transcription factor and Gene expression. His studies in Computational biology integrate themes in fields like Genetics, Proteomics, Nucleic acid, Gene and Bioinformatics. In his research, Ola Söderberg performs multidisciplinary study on In situ and Messenger RNA.
Proximity ligation assay, Cell biology, In situ, Protein–protein interaction and Molecular biology are his primary areas of study. The concepts of his Proximity ligation assay study are interwoven with issues in Extracellular vesicles, DNA, Pathology, Microscopy and Flow cytometry. Ola Söderberg has included themes like Microfluidics, Molecular diagnostics and Ligation in his DNA study.
His work in Cell biology addresses issues such as Regulation of gene expression, which are connected to fields such as Melanocyte, Transcription factor and Melanin. His work in Protein–protein interaction tackles topics such as Computational biology which are related to areas like Förster resonance energy transfer and Drug target. The study incorporates disciplines such as Mutagen, Virology and Borna disease virus in addition to Molecular biology.
The scientist’s investigation covers issues in Molecular biology, Proximity ligation assay, Cancer research, Chain reaction and Flow cytometry. Ola Söderberg has researched Molecular biology in several fields, including Myeloid leukemia, Fusion transcript, ABL and Minimal residual disease. His Proximity ligation assay research is multidisciplinary, relying on both Pathology, Tissue sections and Molecular medicine.
His biological study spans a wide range of topics, including Immunohistochemistry, Immunology, Monoclonal, Catenin and Chronic lymphocytic leukemia. His Flow cytometry research integrates issues from Biophysics, Nucleic acid thermodynamics, Sequence and Protein–protein interaction. Ola Söderberg conducted interdisciplinary study in his works that combined In situ and Cell biology.
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Direct observation of individual endogenous protein complexes in situ by proximity ligation
Ola Söderberg;Mats Gullberg;Malin Jarvius;Karin Ridderstråle.
Nature Methods (2006)
Characterizing proteins and their interactions in cells and tissues using the in situ proximity ligation assay
Ola Söderberg;Karl-Johan Leuchowius;Mats Gullberg;Malin Jarvius.
The F-Box Protein Skp2 Participates in c-Myc Proteosomal Degradation and Acts as a Cofactor for c-Myc-Regulated Transcription
Natalie Von Der Lehr;Sara Johansson;Siqin Wu;Fuad Bahram.
Molecular Cell (2003)
c-Myc associates with ribosomal DNA and activates RNA polymerase I transcription.
Azadeh Arabi;Azadeh Arabi;Siqin Wu;Karin Ridderstråle;Holger Bierhoff.
Nature Cell Biology (2005)
Somatically mutated Ig VH3-21 genes characterize a new subset of chronic lymphocytic leukemia
Gerard Tobin;Ulf Thunberg;Anna Johnson;Ingrid Thörn.
In situ detection and genotyping of individual mRNA molecules.
Chatarina Larsson;Ida Grundberg;Ola Söderberg;Mats Nilsson.
Nature Methods (2010)
Chronic lymphocytic leukemias utilizing the VH3-21 gene display highly restricted Vλ2-14 gene use and homologous CDR3s: implicating recognition of a common antigen epitope
Gerard Tobin;Ulf Thunberg;Anna Johnson;Inger Eriksson.
Subsets with restricted immunoglobulin gene rearrangement features indicate a role for antigen selection in the development of chronic lymphocytic leukemia.
Gerard Tobin;Ulf Thunberg;Karin Karlsson;Fiona Murray.
Proximity ligation assays : a recent addition to the proteomics toolbox
Irene Weibrecht;Karl-Johan Leuchowius;Carl-Magnus Clausson;Tim Conze.
Expert Review of Proteomics (2010)
A new perspective: molecular motifs on oxidized LDL, apoptotic cells, and bacteria are targets for chronic lymphocytic leukemia antibodies
Anna Lanemo Myhrinder;Eva Hellqvist;Ekaterina Sidorova;Anita Söderberg.
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